Synthesis of Translatable mRNA for Phytochrome during Imbibition in Embryonic Axes of Pisum sativum L.

The activity of translatable mRNA for phytochrome was measuredin excised embryonic axes of Pisum sativum L. during imbibitionboth in the dark and under continuous irradiation with whitelight. When measured in cell-free protein synthesis systemsof both rabbit reticulocyte lysate and wheat germ extract, theactivity of translatable mRNA for phytochrome was not detectedin dry quiescent axes but increased rapidly after imbibitionin the dark. After 24 h imbibition, the level of translatablemRNA for phytochrome, in terms of the incorporation of [³⁵S]methioninein the wheat germ system, was ca. 0.0034% of total translatablemRNA. In the presence of 0.5 µg ml^–1 -amanitin,the appearance of translatable mRNA for phytochrome was inhibitedby 60%, while 2 µg ml^–1 -amanitin was almost completelyinhibitory. This indicates that the synthesis of translatablemRNA for phytochrome in embryonic axes begins upon imbibition. When the axes were imbibed under continuous white light, theactivity of phytochrome mRNA increased as rapidly during thefirst 3 h as in the dark. After this time, the activity wasmarkedly lower than in the dark. Nevertheless, during the 24h of imbibition, activity in the light was always found to bemore than half of that in the dark. These results indicate thatin germinating pea axes the level of translatable mRNA for phytochromeis partially repressed by light. (Received June 5, 1985; Accepted September 2, 1985)     

Photoregulation of Phytochrome Synthesis in Germinating Embryos of Avena sativa L.

Hilton, J. R. and Thomas, B. 1987. Photoregulation of phytochromesynthesis in germinating embryos of Avena sativa L.—J.exp. Bot. 38: 1704–1712. The effect of light on the accumulation of phytochrome in germinatingAvena embryos was determined. A quantitative ELISA using monoclonalantibody AFRC MAC 56 was used to measure specifically type 1(or dark) phytochrome. A pulse of red light given after 14 himbibition but prior to the onset of type 1 phytochrome synthesis,strongly inhibited subsequent type 1 phytochrome accumulation.This effect of red light at 14 h was reversible by far-red lightindicating the involvement of phytochrome. Red light also inhibitedphytochrome synthesis after 18 h and 24 h imbibition but after24 h, far-red light did not reverse the effect. The effect ofred light treatment at 18 h was reversed by giving a pulse offar-red light at any time up to 30 h. Seed germination was notinfluenced by light under the conditions of these experiments.It is proposed that type 2 (or light) phytochrome may be responsiblefor photoregulation of type 1 phytochrome synthesis in germinatingAvena embryos. Key words: Photoregulation, phytochrome, seed.     

Cross-linking Phytochrome to its Receptor in situ using Imidoesters

Phytochrome can be cross-linked to a particulate fraction usingimidoesters, namely dimethy adipimidate (DMA) and dimethyl suberimidate(DMS). DMS was more effective than DMA. Cross-linking of phytochrometo its in situ receptor effected by DMS occurred in red light-irradiatedcoleoptiles. If DMS cross-linking was carried out prior to redlight irradiation there was very little formation of particulatephytochrome. Phytochrome in the particulate fraction obtainedby in situ DMS cross-linking was totally resistant to the solubilizingeffect of washing with solutions of high salt concentrationand high pH and was indistinguishable spectro-scopically fromthe phytochrome in untreated coleoptiles. DMS cross-linkingof phytochrome to its assumed receptor in situ preferentiallyprotected it from destruction following red light irradiationand also prevented it from dissociating from its receptor followingR/FR¹ irradiation when incubated subsequently in the dark. Thesecharacteristics of phytochrome in DMS-treated coleoptiles matchedthose observed using glutaraldehyde as the cross-linking reagent.It is therefore concluded that earlier results obtained usingglutaraldehyde are not peculiar to that reagent and can be duplicatedreadily using more defined bifunctional cross-linkers.     

Changes in the Content of Phytochrome I and II Apoproteins in Embryonic Axes of Pea Seeds during Imbibition

The contents of phytochrome I and II in crude extracts fromembryonic axes of Pisum sativum cv. Alaska seeds were immunochemicallydetermined using purified pea phytochrome I and II as standards.We have produced and used three different types of mouse monoclonalanti-pea phytochrome antibodies (mAP) such as one reacting preferentiallywith phytochrome I, one with phytochrome II, and one with bothI and II. Phytochrome II was separated from I in the samplesusing immobilized column chromatography with mAPl. The amountsof two phytochrome species were quantitatively measured withwestern blotting and ELISA. Ca. 0.2 µg /axis of phytochromeI and ca. 0.05 µg /axis of phytochrome II were detectedby ELISA after imbibition for 12 h in the dark, though smallamounts of both were detected in dry axes. Ca. 0.05 µg/axis each of phytochrome I and II were detected by ELISA afterimbibition for 12 h in the light, and the results were confirmedby western blotting. This study showed that phytochrome II isnot green-tissue-specific, being also found in dark-imbibedembryonic axes, and that although light significantly lowersthe content of phytochrome I in the axis, it does not significantlyaffect that of phytochrome II. (Received June 10, 1987; Accepted August 27, 1987)     

In vivo Studies on the Occurrence of Stored mRNA in Embryonic Axes of Vigna unguiculata Seeds

-Amanitin and cordycepin at various concentrations were testedfor their inhibitory effect on the fresh weight increase ofVigna unguiculata embryonic axes after the onset of imbibitionand on the incorporation rate of ³H-labeled leucine into proteinin axes of the 36–38 h stage. -Amanitin at 0.5–5µ/Kg/ml clearly exerted an inhibitory effect on both thefresh weight increase and the protein synthesis. This drug at1 µg/ml, however, showed no significant effect on theprotein synthesis at an early stage of imbibition (4 h), whereascycloheximide was a very potent inhibitor. By experiments inwhich ‘dry’ axes were allowed to imbibe 3H-lebeledadenosine solution for 4 and 12 h in the presence of -amanitin,it was found that poly A⁺RNA was newly synthesized to some extentin axes as early as 4 h after the onset of imbibition and thatthe drug effectively inhibited the poly A⁺RNA synthesis. Theresults may indicate the occurrence of stored mRNA in embryonicaxes of V. unguiculata seeds. (Received June 11, 1983; Accepted August 16, 1983)     

Spectrophotometric characterization of phytochromes in dimorphic cocklebur seeds in relation to capacity for germination

Phytochrome was measured spectrophotometrically in different tissues of the upper (positively photoblastic) and lower (negatively photoblastic) seeds of the cocklebur (Xanthium pennsylvanicum Wallr.). Axial parts of the seeds, in particular parts of the radicle, contained high levels of phytochrome, while cotyledonary parts contained only low levels. These results were consistent with the distribution of the light-sensitive areas of the seeds that were associated with germination. Phytochrome levels in both types of dimorphic seeds increased gradually with increasing duration of dark imbibition for 4–8 h, then the rates of increase in levels of phytochrome accelerated. In both types of seed, some phytochrome was measurable even before imbibition. In the lower seeds, up to 20% of the phytochrome was occasionally observed as P_fr in samples imbibed in darkness for a short time (up to 12 h). A slight blue shift of the peak of P_T in the difference spectrum of phytochrome was observed in the case of lower seeds imbibed for 0–2 h. These results suggest that, to some extent, the lower axes contain dehydrated P_fr or intermediate(s) in the photoconversion of phytochrome. The dark reactions of P_fr were also examined in excised axes of both types of dimorphic seed after they had been pre-imbibed for 16 h in darkness. Dark destruction of P_fr was observed in both types of seed. In addition, net increases in levels of P_r were observed in the dark controls and in the samples irradiated with red light after the level of P_fr diminished. No ‘inverse’ dark reversion from P_r to P_fr was detected. Thus, after 16 h of imbibition, there were no differences in terms of properties of phytochrome between the two types of seed, and the different responses to light of upper and lower seeds might depend mainly on a difference in the physiological state of the two types of seed rather than the properties of phytochrome.     

The kinetics of type 1 phytochrome in green,light-grown wheat (Triticum aestivum L.)

The kinetics of type 1 phytochrome were investigated in green, light-grown wheat. Phytochrome was measured by a quantitative sandwich enzyme-linked immunosorbent assay using monoclonal antibodies. The assay was capable of detecting down to 150 pg of phytochrome. In red light, rapid first-order destruction of the far-red-light-absorbing form of phytochrome (Pfr) with a half-life of 15 min was observed. Following white light terminated by red, phytochrome synthesis was delayed in darkness by about 15 h compared to plants given a terminal far-red treatment. Synthesis of the red-light-absorbing form of phytochrome (Pr) was zero-order in these experiments. Phytochrome synthesis in far-red light was approximately equal to synthesis in darkness in wheat although net destruction occurred in light-grown Avena sativa tissues in continuous far-red light, as has been reported for other monocotyledons. In wheat, destruction of Pfr apparently did not occur below a certain threshold level of Pfr or Pfr/total phytochrome. These results are consistent with an involvement of type 1 phytochrome in the photoperiodic control of flowering in wheat and other long-day plants.Abbreviations ELISA enzyme-linked immunosorbent assay - FR far-red light - HIR high-irradiance response - Pfr farred-light-absorbing form of phytochrome - Pr red-light-absorbing form of phytochrome - Ptot total phytochrome (Pr + Pfr) - R red light The authors wish to thank Prof. Daphne Vince-Prue (University of Reading) for many helpful discussions regarding this work. Hugh Carr-Smith was supported by a Science and Engineering Research Council studentship and Chris Plumpton by an Agricultural and Food Research Council (AFRC) studentship. B. Thomas and G. Butcher were supported by the AFRC.     

Cell Morphogenesis and Macromolecule Synthesis during Phytochrome-controlled Germination of Spores of the Fern, Pteris vittata

The object of this study was to characterize the pattern ofcell morphogenesis and synthesis of nucleic acids and proteinsduring phytochrome-controlled germination of spores of the fern,Pteris vittata. Phytochrome activation and germination wereinitiated in fully imbibed spores by exposure to a saturatingdose of red light. At timed intervals thereafter, spores werefixed in acrolein and embedded in glycol methacrylate for examinationin the light microscope. The first sign of germination, visiblein sections of the spore 12 h after irradiation, was the hydrolysisof storage protein granules. This was followed by a migrationof the nucleus from its central location to one side of thespore. Subsequently, the protoplast enlarged at the site ofthe nucleus and appeared outside the exine as a papillate structure.An asymmetrical division of the protoplast gave rise to a smallcolourless rhizoid cell and a large, chloroplast-containingprotonemal cell. During the early phase of germination, DNAwas synthesized both in the nucleus and cytoplasm as judgedby autoradiography of [³H]thymidine incorporation. [³H]Uridine,a precursor of RNA synthesis, was incorporated into the nucleolusand the rest of the nuclear material of germinating spores.Protein synthesis monitored by [³H]leucine incorporation occurredboth in the nucleus and cytoplasm during the early stage ofgermination, although a strictly cytoplasmic protein synthesiswas observed later. Addition of cycloheximide completely inhibitedgermination of photoinduced spores and incorporation of labelledprecursors of macromolecule synthesis into cellular components.Actinomycin D was much less effective as an inhibitor of germinationand, even in high concentrations of the drug which effectivelyinhibited DNA and RNA synthesis in spores, proteolysis and proteinsynthesis appeared normal. These findings are discussed withrespect to the regulation of nucleic acid and protein synthesisduring spore germination and the role of phytochrome in theprocess.     

Effects of Chilling, Light and Nitrogen-containing Compounds on Germination, Rate of Germination and Seed Imbibition of Clematis vitalba L.

Effects of chilling (5 °C) period, light and applied nitrogen(N) on germination (%), rate of germination (d to 50% of totalgermination; T_50%) and seed imbibition were examined inClematisvitalba L. In the absence of chilling, light and N, germinationwas minimal (3%). When applied alone, both chilling and N increasedgermination. Chilling for 12 weeks increased germination to64%, and 2.5 mM NO^-₃or NH⁺₄increased germination to 10–12%.Light did not increase germination when applied alone, but didwhen applied in combination with chilling and/or N. Half theseed germinated when light was combined with 2.5 mM NO^-₃or NH⁺₄.The influence of chilling, light and/or N on germination wasgreater when combined, than when either factor was applied alone.Both oxidized (NO^-₃) and reduced (NH⁺₄) forms of N increasedgermination, but non-N-containing compounds did not, suggestingthe response was due to N and not ionic or osmotic effects. Without additional N, T_50%decreased from 16–20 d at zerochilling, to around 5 d at 8 and 12 weeks chilling. AlthoughT_50%was not influenced by an increase in NO^-₃or NH⁺₄from 0.5to 5.0 mM , it did increase with additional applied N thereafter.However, the magnitude of the N effect was small compared tothat of chilling. Like germination, seed imbibition increasedwith a longer chilling period, but in contrast imbibition decreasedslightly with increased applied NO^-₃or NH⁺₄. It is argued thatincreased imbibition is not directly related to an increasein total germination, but that it may be related to the rateof germination. Possible mechanisms involved in the reductionin dormancy ofC. vitalba seed are discussed. Clematis vitalba L.; germination; dormancy; imbibition; rate of germination; chilling; light; nitrate; ammonium; nitrogen; phytochrome     

Interactions of seed water content with phytochromeinitiated germination of Rumex crispus (L.) seeds

Light-initiated germination levels of Rumex crispus L. seedswere reduced equally by imbibition in mannitol or polyethyleneglycol 6000 (PEG 6000) solutions of the same w, indicating thatthe effects of each were through w. Reduction of the water contentof the seeds with these osmotica decreased the effectivenessof the far-red absorbing form of phytochrome (P_tr) in causinggermination. However, reduced water content had no effect onthe slopes or saturation points of fluence/response curves whichindicates that has no effect on the number of P_tr receptor sites.The time during which a portion of the seeds were still photoreversibleby far-red light was increased by imbibition in PEG 6000, indicatinga direct effect of w on a reaction involving phytochrome. Noqualitative effect of PEG 6000 on the Onset of secondary dormancywas seen; however, its effect on the relative rate of appearanceof secondary dormancy was equivocal. ¹ Mississippi Agricultural and Forestry Experiment Station cooperating. (Received February 23, 1978; )     

Solute Leakage from Solanum nigrum L. Seeds Exposed to High Temperatures during Imbibition

Exposure of Solanum nigrum L. seeds to high temperatures duringimbibition affected their leakage pattern: (1) The rate of leakageof total electrolytes was markedly increased with elevationof temperature. The increase was highest during the first 3h of imbibition but with a reduced rate thereafter. (2) Leakageof Na⁺ was almost complete after 6 h of imbibition at both temperatures,but much more Na⁺ leaked out at 50?C than at 25?C. (3) A markedincrease in leakage of K⁺ occurred after 24 h of exposure to50?C so that after 96 h three times more K⁺ leaked out at 50?Cthan at 25?C. (4) After 6 h of imbibition Ca11 and Mg⁺⁺ continuedto leak out at 25?C and at 50?C at a similar rate. (5) Imbibitionat an elevated temperature induced a marked increase in theleakage of both nucleic acids and proteins. (6) Malate dehydrogenasewas not detected in the leachate at 25?C, but was found after48 h at 50?C. It is assumed that this enzyme was of cytoplasmicorigin, indicating heat damage to membranes. The possible roleof the above phenomena in the loss of viability of the seedsdue to exposure to high temperature during imbibition is discussed. Key words: Leakage, Germination, S. nigrum     

Transient down-regulation of phytochrome mRNA abundance in etiolated cucumber cotyledons in response to continuous white light

Phytochrome mRNA abundance decreased to 20% of the initial level in etiolated cucumber (Cucumis sativus L.) cotyledons exposed to continuous white light. Unexpectedly, by 12 hours of continuous white light, phytochrome mRNA had reaccumulated to 60% of the control level. High stringency RNA blot analyses suggest that it is the mRNA encoding type I phytochrome that reaccumulates.     

Gene Activity during Germination of Spores of the Fern, Onoclea sensibilis: RNA and Protein Synthesis and the Role of Stored mRNA

Pattern of ³H-uridine incorporation into RNA of spores of Onocleasensibilis imbibed in complete darkness (non-germinating conditions)and induced to germinate in red light was followed by oligo-dTcellulose chromatography, gel electrophoresis coupled with fluorographyand autoradiography. In dark-imbibed spores, RNA synthesis wasinitiated about 24 h after sowing, with most of the label accumulatingin the high mol. wt. poly(A)^–RNA fraction. There was noincorporation of the label into poly(A) ⁺ RNA until 48 h aftersowing. In contrast, photo-induced spores began to synthesizeall fractions of RNA within 12 h after sowing and by 24 h, incorporationof ³H-uridine into RNA of irradiated spores was nearly 70-foldhigher than that into dark-imbibed spores. Protein synthesis,as monitored by ³H-arginine incorporation into the acid-insolublefraction and by autoradiography, was initiated in spores within1–2 h after sowing under both conditions. Autoradiographicexperiments also showed that the onset of protein synthesisin the cytoplasm of the germinating spore is independent ofthe transport of newly synthesized nuclear RNA. One-dimensionalsodium dodecyl sulphate-polyacrylamide gel electrophoresis of³⁵S-methionine-labelled proteins revealed a good correspondencebetween proteins synthesized in a cell-free translation systemdirected by poly(A) ⁺RNA of dormant spores and those synthesizedin vivo by dark-imbibed and photo-induced spores. These resultsindicate that stored mRNAs of O. sensibilis spores are functionallycompetent and provide templates for the synthesis of proteinsduring dark-imbibition and germination. Key words: Onoclea sensibilis, fern spore germination, gene expression, protein synthesis, sensitive fern, stored mRNA     

Water Uptake and Protein Synthesis in Germinating Wheat Embryos under the Osmotic Stress of Polyethylene Glycol

The effect of osmotic stress on wheat-seed germination was testedby imbibition in aqueous polyethylene glycol solutions at differentconcentrations. The experiments were designed to allow blockingand the subsequent recovery of germination by 12 h or 24 h pre-imbibitionof seeds in osmoticum, followed by transfer to water. Seedswere alternatively presoaked in water for 12 or 24 h, then transferredto polyethylene-glycol solutions to study the induced blockingof germination. Water content and [³H]leucine incorporationinto embryo tissues (as a measure of in vivo protein synthesis)were determined over a 48-h imbibition period. A close relationshipwas established overall between hydration status and proteinsynthesis rate. Osmotic stress seems to have a strong influenceupon the quantitative synthesis of proteins, suggesting thatthis biochemical activity is associated with the regulationof the germination process. Triticum durum, embryo, osmotic stress, water uptake, protein synthesis     

A Comparison of Seed and Seedling Phytochrome in Avena sativa L. using Monoclonal Antibodies

Hilton, J.R. and Thomas, B. 1985. A comparison of seed and seedlingphytochrome in Avena saliva L.using monoclonal antibodies.—J.exp. Bot. 36: 1937–1946.The kinetics of phytochrome accumulationduring imbibition and germination of seeds of Avena saliva L.cv. Saladin has been determined in vivo by spectrophotometryand in extracts by using Enzyme–Linked Immunosorbent Assay(EL1SA). In vivo measurements show two phases of phytochromeincrease. The first occurs during the initial 2 h of imbibitionand is associated with the hydration of the seed proteins; thesecond larger increase begins after 16 h, due probably to denovo synthesis. An ELISA using monoclonal antibodies purifiedfrom dark grown Avena seedlings detected only the second increasein phytochrome content. Mixing experiments indicate that theinability to detect phytochrome by ELISA during the first 16h is not due to the presence of inhibitors in the extracts.It is concluded that pre–existent seed phytochrome isantigenically dissimilar to seedling phytochrome. These twopools of phytochrome are stable and unstable respectively withregard to Pfr destruction. Key words: Immunology, phytochrome, seed     

Phytochrome-mediated changes in the ATP content of Kalanchoë blossfeldiana seeds

One short red (R) irradiation increases the ATP content of Kalanchoë blossfeldiana Poelln. cv Feuerblüte seeds before onset of germination. Phytochrome control is demonstrated by the full R/far-red light (FR) reversibility of the effect in water imbibed seeds. In seeds imbibed in the presence of gibberellin A₃ (GA₃, one short R exposure already increases the ATP content when given 2h after start of imbibition, showing phytochrome control at the energy-metabolic level when one R pulse cannot yet induce germination. After longer imbibition periods in the presence of GA₃, one short FR irradiation also increases the ATP content of ungerminated Kalanchoë seeds. The time course of the ATP levels after a R or FR germination inducing irradiation shows an initial increase that clearly preceeds germination. A second increase starts about 15 h after irradiation and is most probably the consequence of the germination itself. The results suggest that, in Kalanchoë seeds, the increase in ATP levels, induced by irradiation(s) and preceding germination, is a phytochrome-mediated process, supplying energy, required for germination.     

Characterization of Green Tissue-Specific Phytochrome Isolated Immunochemically from Pea Seedlings

Phytochrome was isolated and purified from light-grown pea (Pisumsativum) seedlings and compared with that from dark-grown seedlingsin terms of spectral and immunochemical properties. Approximately40% of phytochrome in the brushite eluate prepared from light-grownpea tissue bound with a monoclonal anti-pea phytochrome antibody(mAP3), but the remaining 60% did not. Both phytochrome fractionsshowed a typical photoreversible absorbance change after alternatered and far-red actinic irradiations, which was similar to thatof phytochrome from etiolated pea tissue. The peptide mappingof the mAP3-bound phytochrome from light-grown tissue was essentiallythe same as that of the mAP3-bound phytochrome from etiolatedtissue. However, the digestion pattern of the phytochrome thatwas prepared from light-grown tissue but which did not bindto mAP3 was obviously different from that of mAP3-bound phytochrome.Polyclonal anti-pea phytochrome antibodies and mAP5 and 10,however, bound to both the phytochromes. These results suggestthat light-grown tissue contains two phytochrome pools whichare distinct from each other with respect to the primary structureof the phytochrome polypeptide but which share a few commondeterminant sites. ¹ Permanent address: Department of Biology, Faculty of Science,Tokyo Metropolitan University, Fukazawa, Tokyo 158, Japan (H.A.), and Department of Botany, Faculty of Science, Universityof Tokyo, Hongo, Tokyo 113, Japan (M. F.).     

Photoinduction of Spore Germination in a Fern, Mohria caffrorum

Irradiation of spores of the fern Mohria caffrorum Sw. witheither red light (67.4 µW cm^–2) or far-red light(63.2 µW cm^–2) for a period of 24 h induced maximumlevels of germination. Brief irradiations with blue light (127.6µW cm^–2) administered before or after photoinductioncompletely nullified the effects of red or far-red light; however,with prolonged exposure to blue light, germination levels roseto near maximum. The similar effects of red and far-red lightin promoting spore germination makes the involvement of phytochromein this process questionable. Based on energy requirements,the promotive and inhibitory phases of blue light appear toinvolve independent modes of action. Mohria caffrorum, ferns, spore germination, photoinduction, phytochrome     

Isolation of cDNA for Pea Phytochrome Using an Expression Vector

Partially purified phytochrome mRNA was obtained from etiolatedpea epicotyls by polyribosome immunoprecipitation or by sizefractionation of total poly(A)⁺RNA, and used for the synthesisof double-stranded complementary DNA (cDNA). cDNA librarieswere constructed using an Escherichia coli expression vector,pUC9, and screened for phytochrome cDNA by colony immunologicalassay. Nine colonies were found to produce a 27 kDa polypeptidethat was reactive to both polyclonal and monoclonal antipeaphytochrome antibodies. The plasmids from these colonies containedcDNA inserts of 1.2 or 2.0 kbp. Hybridization-arrest translationassay verified that the cDNA clones contained a sequence codingfor phytochrome polypeptide. RNA blot hybridization analysisindicated that the cDNA hybridized to a 4.1 kb poly(A)⁺RNA indark-grown pea. (Received March 22, 1986; Accepted June 13, 1986)